JP2522958B2 - Ice maker and its blade assembly - Google Patents

Abstract

An ice-making machine (l0) includes a plurality of heat exchangers (24) disposed inside a housing (l2) and each having an inlet (34) and an outlet (36) to permit circulation of coolant therethrough. Each of the heat exchangers includes a pair of oppositely directed, corrugated heat exchange surfaces (25) to transfer heat from the fluid within the housing to the coolant. Ice-making regions (38) are disposed between the heat exchangers. These regions each have an inlet and an outlet (42) to enable fluid to circulate therethrough. Blade assemblies (46) are provided in each of the ice-making regions to co-operate with the heat exchangers to inhibit deposition of ice on the heat exchangers. These blade assembles each include at least one blade (58) of complementary shape to the corrugated heat exchange surfaces to contact respective ones of the surfaces. The blade assembles are rotatable about an axis generally perpendicular to the plane containing the surfaces. Drive means (20) rotate the blade assemblies at a rate such that the interval between successive passes of the blades is insufficient to permit crystallization of ice on the surfaces.

Description

The present invention relates to an ice making machine, and more specifically to a corrugated plate heat exchange device used in the ice making machine.

The contents of U.S. Patent Application No. 739,225 are hereby incorporated by reference, which discloses a heat exchange device suitable for ice making. The heat exchange device comprises a housing having a liquid inlet and a liquid outlet. A plurality of heat exchange devices are arranged in the housing, and each heat exchange device is provided with an inlet and an outlet through which the coolant is circulated. Each heat exchange device is provided with a pair of heat exchange surfaces facing in opposite directions to allow heat exchange between the liquid in the housing and the coolant. Install the blade assembly on a rotating shaft that passes through the center of the housing. The blade assembly consists of a disk with a plurality of blades hinged on both sides. One blade is directed at the surface of one heat exchange device and the other blade is directed at the surface of another heat exchange device.
The blade rubs against the surface of the heat exchanger to prevent ice crystals from forming here.

The object of the present invention is to improve the efficiency of the heat exchange device described above.

Accordingly, the present invention provides an ice maker that includes a plurality of heat exchange devices disposed within a housing, each heat exchange device having an inlet and an outlet through which a coolant is circulated. Each heat exchange device includes a pair of oppositely facing corrugated plate heat exchange surfaces to transfer heat from the liquid in the housing to the coolant. The ice making part is arranged between the heat exchange devices. The ice making sections each have an inlet and an outlet through which liquid can circulate. A blade assembly is provided at each ice making portion to prevent ice from adhering to the heat exchange device in cooperation with the heat exchange device. The blade assemblies each include one or more blades shaped to mate with a corrugated heat exchange surface to contact each surface. The blade assembly is rotatable about an axis that is substantially perpendicular to the plane containing the surface. Then, the blade assembly is rotated by a driving means such as a motor at a speed such that the interval of continuous passage of the blade is not long enough to form ice crystals on the surface.

The use of the corrugated heat exchange device of the present invention increases the heat transfer area and increases the rigidity of the members forming the heat exchange surface. , Has the advantage. A corrugated heat exchange surface does not tend to warp as easily as a flat heat exchange surface, and therefore less blade wear. To contact the heat transfer surface, a blade having a shape that meshes with the surface is used to ensure that ice crystals do not adhere to the surface of the heat exchange device.

Referring to FIGS. 1 and 2, the ice making machine 10 has a ceiling wall 1
4, it can be seen that it includes a housing 12 having a side wall 16 and an end wall 18. The end wall portion 18 is square in plan view and forms a box shape together with the ceiling wall portion 14, the bottom portion 15 and the side wall portion 16.

A hollow rotary shaft 20 having an open end 21 is provided such that each open end 21 can be rotatably connected to each of the salt water introducing pipes 25 and penetrates the housing between both end wall parts 18. It is growing. The shaft is rotatably supported at both ends by bearings 22 outside the housing and is rotatable by a motor.

As best seen in FIGS. 1 and 3, a plurality of heat exchange devices 24 are spaced within the housing 12. Each heat exchange device 24 is composed of a pair of discs 25, which are provided with an opening 28 into which the shaft 20 is inserted,
Spaced by an inner gasket 29 and an outer gasket 30. A spiral ring or honeycomb structure (not shown) may be placed between each pair of discs 25 and adhered by suitable means to improve structural rigidity. The disc 25 has corrugations 27 extending circumferentially to provide a corrugated heat exchange surface 26, as best seen in FIG. Each of the disks 25 near the lower end 32 has a housing
It is supported by a pair of support portions 33 extending in the longitudinal direction of the housing 12 inside the housing 12. Each heat exchange device 24 has an inlet 34 at the upper end 31 and an outlet 36 at the lower end 32. Alternatively, the inlet may be provided at the lower end 32 and the outlet at the upper end 31.

An ice making portion 38 is disposed between each pair of heat exchange devices 24. An ice making section outlet 42 is at the lower end 44 of each ice making section. A blade assembly 46 is located at each ice making portion 38. 1
A plurality of blade assemblies arranged in one ice making section are supported by a common carrier, a retaining ring 50. Each blade assembly 46 includes a pair of arms 48 mounted generally perpendicular to the shaft 20 on a retaining ring 50 secured to the shaft 20.
including. The arm 48 passes through an opening 54 in the shaft 20,
It communicates with the shaft 20. The arm 48 is tubular and has a plurality of holes 56 arranged vertically at intervals. Two blades 58
The length of the arm extends almost the entire length of the arm, with the hinge 59 and arm 48
Each is connected like a pivot. Fig. 3 and
As can be seen in Figure 5A, each blade 58 has a substantially straight edge 61 that is hinged to the arm and a heat exchanger surface 26.
And a knurled edge 63 shaped to fit the shape of the plate. One blade 58 is hinged to the side of an arm 48 that is positioned towards the heat exchange surface 26 of one heat exchange device, and the other blade 58 is attached to the adjacent heat exchange device. Mounted on the side of the arm which is arranged towards the heat exchange surface of the. A biasing means, torsion spring 62, is connected to blade 58 and arm 48 to direct blade 58 into a position to rub against the surface of each heat exchange surface 26.

In another embodiment, the salt water inlet is located at the bottom of each ice making section and the salt water outlet is located at the top of each ice making section.

During operation, salt water is supplied to both ends 21 of the rotary shaft 20. The salt water flows into the arm 48 through the opening 54 in the shaft 20 and enters the ice making section through the hole 56 in the arm 48. The frozen material enters each heat exchange device 24 through the inlet 34 and the outlet 36.
Get out of. When the frozen material passes through the heat exchange device 24,
It absorbs heat through the heat exchange surface 26 and boils. The salt water in contact with the heat exchange surface 26 is thus extremely cooled. The blade assembly is rotated by shaft 20 so that ice does not adhere to surface 26 and impede heat transfer. Rotation of shaft 20 causes arm 48 to rotate, thereby causing blade 58 to lightly touch each heat exchange surface 26. The movement of the blades removes the supercooled salt water from the immediate vicinity of the surface 26 and distributes it in the main part of the salt solution. Extremely cooled salt water,
It crystallizes on the crystal centers that are present in the solution, which in turn becomes new crystal centers to form steric water crystals in the salt solution, thus promoting ice formation in the crystallization process. The salt solution in a suspended state containing crystallized ice is taken out from the ice making section outlet 42.

Figures 5B through 5F show three embodiments of the blade shown in Figure 5A. In FIG. 5B, instead of using a single blade, several triangular blade sections 64, whose shape corresponds to the corrugated heat exchange surface 26, are hinged.
It is pivotally connected to arm 48 by 66.
A biasing means, a torsion spring 68, is coupled to each section 64 to direct the section 64 toward the heat exchange surface 26.

Figures 5C and 5D show another embodiment of the blade. In this embodiment, there are several blade sections 67, each made of a flat piece of plastic 68, which is V-shaped to match the shape of the heat exchange surface 26. Insert and install the blade 70 between both sides 72, 74 of each V-shaped piece. One end of the coil spring 80 is attached to each blade 70, and the other end is attached to the arm 48. The coil spring 80 directs each piece 68 toward the heat exchange surface 26, and as shown in FIG. 5D, each piece 68 is placed at an angle to the surface and only the edges of the plastic pieces 68 are heat exchange surfaces. Make contact with 26. Figures 5E, 5F and 5G show alternative embodiments. Here, the blade 75 is wider than the ice making portion and is provided with a corrugated edge 76 from which the corrugated lip portion 78 descends. These edges 76
The shape corresponds to the shape of the heat exchange surface 26 defining the ice making portion. The blade assembly is provided with a thin end 81 (Fig. 5G) and extends from the blade attached to shaft 20 rather than arm 48. The blade is twisted at an angle with respect to the end 81 and is mounted between the heat exchange surfaces defining the ice making portion so that the edge 76 and lip 78 respectively contact the opposing heat exchange surface 26. To The end 81 exerts a twisting force on the blade 75 to act as a deflecting means and bring the blade 75 into contact with the heat exchange surface 26. Alternatively, the end 81
The same thickness can be used to attach it to the shaft 20 like a pivot and make an angle.

6 and 7 show another embodiment of the present invention. Elements of this embodiment that correspond to elements in the embodiments shown in FIGS. 1 through 4 have the same reference number followed by the letter “H”. This embodiment was designed to reduce freezing and alleviate some of the problems that may occur when freezing occurs in any of the individual ice making sections. Normally, when freezing occurs, the blades of the frozen part will not rotate with the shaft,
This will result in damage to the equipment.

As can be seen from these figures, this embodiment is similar to the embodiment shown in FIGS. 1 to 4, except that the sleeve 52H is connected to the shaft 20H by a frangible shear pin 82. different. In addition to the blade assembly 46H, a pair of scrapers 84 facing each other at exactly opposite positions
It is supported by 52H. These scrapers have approximately the same shape as the blade assembly 46H, but with the edge 86 away from the heat exchange surface.

If freezing occurs during operation, the scraper 84 scrapes off any excess ice formed on the heat exchange surface 26H. If there is too much ice on the scraper to remove it,
That is, when the rotational load applied to the retaining ring 50H exceeds a predetermined value, the shear pin 82 is broken and the sleeve 52H
The shaft 20H has a mounting structure that allows the shaft 20H to rotate freely after releasing the fixed state between the shaft 20H and the shaft 20H.

Another embodiment for eliminating the problems encountered during freezing is shown in FIG. Elements similar to those described above are designated by the same reference numeral followed by the letter "J." In this embodiment, the sliding device is the interlocking keyway 88.
The first braking pad 90 is fixed to the sleeve 52J with the second braking pad 92 fixed to the shaft 20J with the connecting key groove 91. A ring 94 is attached to the shaft adjacent to the braking pad 92, and the ring 94 and the braking pad are attached.
A spring 96 is disposed between the first brake pad 92 and the second brake pad 92.
Contact the braking pad 90.

During normal operation, due to the frictional force between both braking pads,
The sleeve 52J and the shaft 20J rotate in common. If frozen, the sleeve 52J is prevented from rotating and the braking pad 9
The frictional force between 0 and 92 is overcome to cause relative rotation between sleep 52J and shaft 20J. The braking pad can be housed in a housing (not shown) if desired to prevent interference from the ice making environment. This sliding device allows for the common rotation of the sleeve 52J and shaft 20J under normal circumstances, such as shear pins, friction couplings, and the like, and depending on how much the sleeve is prevented from rotating if freezing occurs. Can be replaced by any device that would be obvious to one of ordinary skill in the art.

It should be understood that the preferred embodiments of the invention can be modified within the scope of the invention as described and claimed. Any number of heat exchange devices 24 and ice making portions 38 may be provided. The ice making portion 38 is provided with one inlet and one outlet so that liquid can be transmitted between the ice making portions. Also, the blade 58 may be moved by a rotating disk instead of the arm 48.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view of a heat exchange device partially shown in section, FIG. 2 is a side view of the heat exchange device shown in FIG. 1, and FIG. 3 is FIG. FIG. 4 is a sectional view of a part of the heat exchange device shown in FIG. 4, which is directed in the direction of arrow A in FIG. 3, and FIG. 5A is a front view of the blade assembly used in the heat exchange device shown in FIG. ,
5B is a front view of another embodiment of the blade assembly used in the heat exchange apparatus of FIG. 1, and FIG. 5C is another embodiment of the blade assembly used in the heat exchange apparatus of FIG. FIG. 5D is a perspective view of the blade assembly of FIG. 5C, FIG. 5E is a front view of yet another embodiment of the blade assembly, and FIG. 5F is line F of FIG. 5E. FIG. 5G is a front view of the blade of FIG. 5E mounted on a shaft, FIG. 6 is a portion of another embodiment of a heat exchange device similar to that shown in FIG. FIG. 7 is a sectional view, FIG. 7 is a view in the direction of arrow B in FIG. 6, and FIG. 8 is a partially sectional side view of another embodiment of the embodiment of FIG.

Claims (5)

(57) [Claims] 1. A housing, disposed in the housing, each having a pair of diametrically opposed heat exchange surfaces having an inlet and an outlet for circulating a coolant therethrough, At least one of the surfaces has a concentric circular corrugation, and is arranged between a plurality of heat exchange devices that transfer heat from the fluid in the housing to the coolant, and each of the heat exchange devices is arranged between the heat exchange devices. An ice making portion having an inlet and an outlet so that the ice can be circulated, and each of the ice making portion is arranged to prevent ice from adhering to the heat exchange surface in cooperation with the heat exchange device. A blade assembly including at least one blade shaped to complement and contact each of the heat exchange surfaces, the blade assembly being rotatable about an axis substantially perpendicular to the surface including the heat exchange surfaces; assembly An ice making machine comprising: drive means for rotating the blade assembly at a speed such that successive body passage intervals prevent the formation of ice crystals on the heat exchange surface. 2. One heat exchange surface of a heat exchange device is directed to one heat exchange surface of another heat exchange device, each of the blade assemblies being supported by a common carrier and rotating in unison. A set of blades, one set of blades being directed towards one of said heat exchanging devices and the other set of blades being facing towards said other heat exchanging device. The ice machine described in the item. 3. Ice machine according to claim 2, characterized in that each of the blades is deflected towards the heat exchange surface by a deflection means. 4. A mounting structure capable of releasing the fixed state between the common carrier and the rotary shaft for driving the common carrier when the rotational load applied to the common carrier exceeds a predetermined value. The ice-making machine according to claim 2 or 3, which is characterized. 5. A blade assembly suitable for rubbing a corrugated heat exchange surface of a corrugated heat exchange surface having a corrugated corrugated heat exchange surface, the corrugated heat exchange surface including the corrugated heat exchange surface. At least one blade that is rotatable about an axis that is substantially perpendicular to a plane and that is shaped to complement the corrugated heat exchange surface, and said blade for maintaining contact with said surface And a deflection means for deflecting the heat transfer surface toward the heat exchange surface.